Answer :
Answer:
[tex]0.75[/tex]
Explanation:
Given frequency of the two alleles i.e "B" and "b" are equal .
As per Hardy–Weinberg equilibrium, sum of frequency of the two alleles is equal to one.
i.e [tex]p+ q= 1\\[/tex]
Since [tex]p=q\\[/tex]
[tex]p[/tex] and [tex]q[/tex] will be equal to 0.5
Frequency of genotype "BB"
[tex]= p^{2} \\= 0.5^{2} \\= 0.25[/tex]
Frequency of genotype "bb"
[tex]= q^{2} \\= 0.5^{2} \\= 0.25[/tex]
As per second equation of Hardy–Weinberg equilibrium,
[tex]p^{2} + q^{2} + 2pq=1[/tex]
Substituting the values of p and q in above equation we get -
[tex]0.25+0.25+2pq=1\\2pq = 1-0.25-0.25\\2pq = 0.5[/tex]
Red beetles have genotype BB and Bb
number of red beetles with genotype (BB)
[tex]= 0.25 * 10000\\= 2500[/tex]
number of red beetles with genotype (BB)
[tex]= 0.5 * 10000\\= 5000[/tex]
Total red beetles
[tex]2500+ 5000= 7500\\[/tex]
Frequency of red beetles
[tex]= \frac{7500}{10000} \\= 0.75[/tex]